Positioning control system having an extended working zone control transformer synchro



May l5, 1962 1 U. c. KELLING 3,035,214

POSTTIONINO CONTROL SYSTEM HAVING AN EXTENDED WORKING ZONE CONTROL TRANSEORNER sYNcHRO 6 Sheets-Sheet 1 Filed July 5l, 1959 L. U. C. KELLING NG CONTR May `l5, 1962 3,035,214 POSITTONI OL SYSTEM HAVING AN EXTENDED WORKING ZONE CONTROL TRANSFORMER SYNCHRO 6 Sheets-Sheet 2 Filed July 3l, 1959 May l5 1962 UT c. KELLING 3 035 21 POSITIONING CONTROL SYSTEM HAVING AN 4 EXTENDED WORKING ZONE CONTROL TRANSFORMER SYNCHRO Flled July 31. 1959 6 Sheets-Sheet 3 SWITCH NO.5 FIFTH DIGIT sw|TcH No.3 Tmno man SOURCEGO UP SCALE DOWN SCALE DIRECTION SIGNAL SWITCH NO 2 SECOND DIGIT FIRST DIGIT SUPPLY VOLTAGE #SPR-I e INVENTORI LEROY U.C. KELLING TTORNEY May l5, 1962 LA u. c. KELLING 3,035,214

POSITIONING CONTROL SYSTEM HAVING AN EXTENDED WORKING ZONE CONTROL TRANSFORMER SYNCHRO Filed July 51, 1959 6 Sheets-Sheet 4 SUPPLY START swITcH FIG-5 SUPPLY voLTAGE- VOLTAGE 257% um i POITTAISIING PCR-I SPR 2 o LAY SPR l TIME l STR'G l DELAY RELAY TDR \W LocKED IN ToR-I TIMING Q/(o RELAY LTR LTR-I fsYNcHRoNIzINs LTR-2 TEST RELAY STR sYR-s sTR-T sYR-4 TDR-2 SPR-3 LooP coNTAcToR Lc 2 LC STR-8 EMR-l v #57 -vfo-TDR-B PosITIoNING v O Lc-3 (svPn-I LTR-3 COMPLETE RELAY PcR-a PCR FIGA sT T Po ITIONING AR S '.ossEc F RELAY sPR TEsT TIME DELAY\ IPER'OD n RELAY TDR /f I 'u LocI En IN TIMING I RELAY LTR LH ,o5sEc.

: TEsT i sYNcHRoNIzING-\ PERIOD TEST RELAY sTR sYNcI-IRoNIzING y RELAY sYR E RRoR MoNIToRINca`!* |-`|r RELAY EMR LooP coNTAcToR""- f-T Lc I PosITIoNING coMI LETE RELAY PcR o TIME T INVENTORI LEROY U.C.KELL|NG,

BY ggTToRNEY.

May 15, 1962 U. c. KELLTNG 3,035,214

POSITIONINO CONTROL SYSTEM HAVING AN EXTENDED WORKING ZONE CONTROL t TRANSFORMER SYNCHRO Flled July 3l, 1959 6 Sheets-Sheet 5 FIRST DIGIT OF INSTRUCTED NUMBER TEST NUMBER 3 4 4 4 8 8 8 8 O I DIRECTION SIGNAL D D D D U U U U D D FIG.6.

T TEsT NUMBER sYNcHRoNlzms RELAY PICKUP THRESHOLD SELSYN $|GNAL slGNAL f `QTRAVEI. l f

WAVE-|27 u, E 0""3 UAV v g o loVao 3o se X 5o so 7o W90 f INSTRucTEO NUMBER TRAVEL 60-000 POSITION INVENTORI LEROY U.C. KELLII'IIG,

BT/W' HlgTToRNE'Y. I

May 15, 1962 L. u. c. KELLING 3,035,214 POSITIONING CONTROL SYSTEM HAVING AN EXTENDED WORKING ZONE CONTROL TRANSPORT/IER syNcHRo Filed July 31. 1959 s sheets-sheet e EXPANDED TRAVEL RELAY DISCRIMINATOR ZONES FOR CONTINUOUS ROTATIONALTRAVEL ILLUSTRATED FOR NUMBERS BETWEEN 3000 AND 3999.

SELSYN REVOLUTION INSTRucTED No.

.a .9 .o .I .2 .3 4 .5 .S .T .s .9 .o .I .2 I l DOWN BSYCAl-E ALTERNATE TEST DIGIT=3HIGHER THAN FIRST DIGIT DISCRIMINATOR PHASE oF RELAY DIScRIMINAToR SAME AS DIAGRAM SYR P.u. 3ooo SYR D o. j

UP sgg-E ALTERNATE TEST D|GIT= 3 LowER THAN FIRST DIGIT DISCRIMINATOR PHASE oF RELAY DIscRIMINAToR REvERSED FRoM DIAGRAM SYR Ru. l 3ooo SYR D.o. x

DowN ScALE ALTERNATE TEST DIGIT= 3 LowER THAN FIRST DIGIT FAvoRED PHASE oF RELAY DIScRIMINAToR REvERSED FRoM DIAGRAM sooo SYR D.o.

SYR Pu n) 3444 t uP ScALE ALTERNATE TEST DIGIT= 3 HIGHER THAN FIRST DIGIT FAvoRED PHASE oF RELAY DIScRIMINA'roR SAME AS DIAGRAM SYR P u. 3000 SYR D.o.

INVENTOR:

LEROY U.C. KELLING I ATTORNEY.

United States Patent O 3,035,214 POSITIONING CONTROL SYSTEM HAVING AN EXTENDED WORKING ZONE CGNTROL TRANS- FORNIER SYNCHR() Leroy U. C. Kelling, Waynesboro, Va., assigner to General Electric Company, a corporation of New York Filed July 31, 1959, Ser. No. 830,874 13 Claims. (Cl. B18-2S) The invention relates to a positioning control system, and particularly to a positioning control system that has an extended working zone.

Certain prior art position-ing control systems use one or more selsyn transformers to control a drive device that positions an object at a desired point in the working zone of the system. `If predetermined voltages (generally provided yby a single common transformer) are applied to the stator windings of the selsyn transformers, certain voltages will then appear across the rotor windings of the selsyn transformers. And, if the drive device simultaneously moves the object and the rotor windings in a direction that will place the object at the desired point, the vcircuit parameters can be chosen so that the voltages across the rotor windings will approach a minimum as the object approaches the desired point. The use of the rotor voltages to control the drive device in the arrangement described thus provides a positioning control system. In a positioning control system such as the one just described, unambiguous operation is limited to steps each having a range of no more than one-half of a revolution of the lowest speed rotor winding of the selsyn transformers. Thus, Where one revolution of the lowest speed rotor `winding of the selsyn transformers corresponds to a travel of 100 inches, the range of unambiguous operation is limited to steps that have a maximum range of 50 inches. This range is further limited by other factors. The num-ber of predetermined voltages which can be provided for the stator windings of the selsyn transformer is limited from a practical standpoint. Consequently, interpolation voltages are derived from these predetermined voltages to increase the number of different voltages which may be provided. These interpolation voltages further limit the range to a value which is somewhat less than the 50% range provided -by the lowest speed rotor winding of the selsyn transformers. And, the range is still further limited by certain gear ratios which exist between the rotor windings of the selsyn transformers. In certain positioning control systems having four selsyn transformers which provide a resolution accurate to five significant figures, the range of a step of operation may be limited to as little as 39.9% of a revolution of the lowest speed rotor winding of the selsyn transformers. Where the desired working zone of the system is greater than the range of a single step of operation, it has been necessary -to perform a plurality of steps to provide the `desired working zone or to provide one or more additional selsyn transformers and associated apparatus.

Accordingly, an object of the invention is to increase the working zone of certain positioning control systems.

Another object of the invention is to extend the working zone of an existing positioning control system, the extended working zone being covered in only one step.

Ano-ther object of the invention is to extend the working zone ot' an existing positioning control system without the addition of a selsyn transformer.

Another lobject of the invention is to provide an improved positioning control system.

Another object of the invention is to increase the working zone of certain positioning control systems and maintain the resolution of such systems without the addition of a selsyn transformer.

Briefly, the positioning control system of the invention contemplates a known follow-up control system having a drive device for positioning `an object by steps each having -a range determined by the known system. The known system may use selsyn devices to provide a predetermined signal vfor effecting the positioning. In accordance with the invention, a so-u-rce produces a direction signal that has a selectable value and that may be coupled to the drive device. With the direction signal coupled to the drive device, the drive device positions the object `from any point in the working zone to a point inside the range of the known system. Means are coupled to the drive device of the known system for first coupling the drive device to the direction signal source so as `to bring the object inside the range, and then coupling the drive device to the predetermined signal source of the known system so as to position the object at the desired location inside the range. Relays and associated circuitry may be used 4to provide the alternative coupling means. With a system in accordance with the invention, the working zone, in which positioning is possi-ble in one step, may be of a revolution of the lowest speed rotor winding.

The invention will be better understood from the following description taken in connection with the accompanying drawing, and its scope will be pointed out in the claims. In the drawing:

FIGURE 1 shows a general block diagram of a positioning control system in accordance with the invention;

FIGURE 2(a) shows a detailed schematic diagram of the selsyn transformers and operating portions of the system shown in the block diagram of FIGURE l;

FIGURE 2(b) shows a detailed schematic diagram of stepping switches and a transformer which provide the voltage sources of the system shown in the block diagram of FIGURE 1;

FIGURE 3 shows various relay windings, armatures, and contacts which are associated with the system of the invention;

FIGURE 4 shows waveforms explaining the operation and sequence of operations of the relays which are associated with the system of the invention;

FIGURE 5 shows a table of test numbers which are provided by the test signal source of the system for providing the extended working zone;

FIGURE 6 shows waveforms lfor explaining the operation of the system and its extended working zone; and

FIGURE 7 shows waveforms illustrating four modes of operation of a rotational positioning control system in accordance with the invention.

The connections between FIGURES are indicated by appropriate legends at the edges of the figures. Leads bearing the same legends are to be considered as being connected together.

2(61) and 2(b) General Description and Operation A positioning control system having the extended working zone provided in accordance with the invention is shown in the simplified general block diagram in FIG- URE l. The system comprises a plurality of selsyn transformers 1t), 12, 14, 16 each having stator windings or stators and associated rotor windings or rotors. rality of predetermined or programmed voltage sources 20, 22, 24, 26 are applied Ito the respective stators of the selsyn transformers 10, 12, 14, 16 so as to cause a certain voltage to be present across or to be induced in each of the respective rotors of the selsyn transformers 10, 12, 14, 16. The rotors of the selsyn transformers are coupled to a mixer circuit 30, such a mixer circuit being shown and described `as a takeover circuit in Patent No. 2,7 6.4,- 720 -issued to L. U. C. Kelling on September 25, 1956. The mixer circuit 3()` effectively serves to select the voltages or signals presented by the rotors and their respective interpolation voltages in a sequential manner beginning with the selsyn transformer 11i which is associated with the first instructed digit and which isthe lowest speed transformer, and ending with the `selsyn transformer 16 which is associated with the fourth and fifth instructed digits and which is the highest speed transformer. The output signal from the mixer circuit 3d is coupled to a discriminator 34, which may be substantially the same as the discriminator shown and taught in the above-mentioned patent. The output signal from the discriminator 34 is applied to a motor control 38, which provides power of sufficient magnitude and a signal of the proper characteristics to control an electric motor 40. The motor control 318 and motor it? are of the type also described in `the above-mentioned patent. The shaft of the motor 40 is coupled to an object 4t2 so as yto move or drive the object 42 in the manner desired, such as in a straightline direction. The shaft of the motor 4t) is yalso coupled (through gears if desired) to the rotor of the selsyn transformer 16 associated with the fourth and yfifth digits,

and the rotor of this transformer 16 is coupled through a system of gears Vto the rotor of thesselsyn Vtransformer V14, associated withk the third digit, and so on through a ,system of gears Vto therotor of the selsyn transformer 1li associated with the first digit. Any suitable gear ratio or ratios may be used, one preferred ratio being a 1:10 ratio between respective rotors to'provide a positioning control that can be easily used with a decimal programmingV of digits. lf the gear ratios shown in FIGURE 1 are used, and if the rotor of the selsyn transformer 1G associated with the first digit operates at 4a given speed (called l-speed), the rotor of `the selsyn transformer 12 associated with the second digit operates at a speed ten times the given speed (or at 1li-speed). Similarly, the

rotor of the selsynV transformer 14 associated with the third digit operates at aY speedV (110D-speed) ten times the speed of the rotor of the selsyn transformers12 of the second digit, or one hundred times the speed of the rotor of the selsyn transformer 11i-associated with the lirst digit. And, likewise, the rotor` of the selsyn transformer 16 associated with the fourth'and fifth digits rotates yat-a speed' (100G-speed) Vten times the speed of the rotor associated associated with the first digit.

Vwith the third digit, or 1G00 times the speed otf the rotor The positioning control system described thus lfar is f known in the art. In its operation, also known inthe art,

suitable predetermined voltages are supplied by the Vsources 20, 22, 24, 26fto the stators of the selsyn transformers'1d,V

12, 14, 16 respectively', the voltages .being properlyrselected to provide a predetermined movement of the object 42 to ia'certain point or position, or' in a certain manner. The voltages across the respective stators of theV transformers 10, V12, 14, 16 set up or induce certainV v'olti ages in the respective rotors of the transformers 1li, 12,V

14,16, the amount'of the Vvoltages so set up or induced 1 being dependent Vupon, theI position of the rotors. The t voltages acrossor induceddnthe rotors and their Vref spective interpolation voltages are applied to the mixer circuit 30, and as mentioned, are then sequentially coupled through the discriminator 3d Vto the motor control 33, which causes the motor atlfto perform some function or Vto, rotate ina certain direction. As the'motort. ro-,I

A pluage is presented to each of the input circuits of the mixerV circuit Bti. Under normal conditions, this position of the rotors will be reached at the same time the object is moved to its desired point `or position. Consequently, no further voltages are applied to the mixer circuit Sti, and the motor 4t) ceases to operate. When a new position of the object ft2 is desired, new voltages are applied to the stators of the selsyn transformers 10, 12, 14, 16 from the sources 21B, 22, 24, 26 and the operation repeats itself until the `object 42 `and the rotors are at the proper position.

As previously mentioned, there are a number of various `factors present in a positioning control system such as just described which may limit, from a practical standpoint, the range of each step of the system to as little as 39.9% of a revolution of the lowest speed or 1-speed rotor, that is the rotor of the selsyn transformer 10l associated with the first digit. `ln accordance with the invention, the system maybe provided with Ian extended working zone of 75% of 'a revolution of the lowest orV lspeed rotor, it being possible to position an object anywhere in this extended Zone in `a single step. Y Positioning outside of this extended zone is also possible in smaller steps. In accordance with the invention, a test signal source Sti is provided, this source 50 supplying certain predetermined test signals or voltages in accordance with the position or point at which the object 42 isV to be located. Signalsv or voltages from the test signal source S Yare alternatively-and selectively applied to the stators of the selsyn transformer 11i associated with the first digit through an armature and contacts STR-2 associated with a synchronizing test relay winding STR (not shown in FiGURE l). Thus, when the system is to effect'movement to a new position, the synchronizing test relay winding STR is energized and the stators of the selsyn transformer 11i are switched yfrom the voltage source 2t? to the test signal source t)` by means of the contacts STR-1 and STR-2. At the same time, contacts STR-3 openVV the circuit between the selsyn transformer and the mixer circuit and contacts'STR-t supply `a relay discriminator circuit S4' with va suitable supply Voltage. If

theV called-for position Vand the actual position ofthe ob- Y ject 'are separated by a distance greater than the rangeof one Stepp-of the' system (e.g.,' more than 39.9% of a revolution of the lowest speed rotor Ywinding of the system mentioned), the signal :from the test signal source Sti in'- Vduces a signal in the rotor of the selsyn transformer 1t) f that exceeds'a predetermined magnitude and theY relay `discriminator S4 energizes'asynchronizig relay winding SYR.V Upon energization of the synchronizing relay wind- Y,

ing SYR, contacts SYR-.l associated with the synchronizing relay winding SYR break Vthe circuit between 'theV .Y

discriminator 34 land the motor control 3:8. VSimultaneously contacts 'SYRLZ close the circuit between a direction signal source 6G and the motor control 38. The di- Y rection-signal source 60 supplies one :of two signals to f cause the motor 40 to operate in the direction needed to move the object 42 toward the desired position or point, n and to move the rotors of the selsyn transformers 10, 12, 14, 16 toward the position of minimum or no voltage.

i As'the rotor of the lowest speed (1-speed) 'selsyn' tra-nsforrner 10 associated with the first digit approaches its de-Y Y sired positionY (that is, comes to' a position that `iswithin VVV39.9% ofa revolution from' the position of minimum g voltage), the voltageV induced'in. this rotor by Vthe test sig? nal source Sti diminishes to a point where it isbelow the Vpreviously mentioned predetermined Ymagnitude. When this occurs, the relay `discriminat'or Seno longer'ene'r'-,

j gizes the synchronizing relay winding SY R.V HenceV the contactsVSYR- and SY-R-2 resume their normal positions. v` so that themotor control 3d is'connected to the discriminatorv 34 and is no longer Vconnected to the direction signal Ysource 60. As will be hereinafter explained, ,when

the synchronizing relay winding SYR is deenergized, the the synchronizing test relay winding STR is likewise deenergized so that ythe lowest or l-speed selsyn trans-former associated with the first digit is again connected to the programmed voltage source through the contacts STR-1 and is disconnected from the test signal source Sti by the contacts STR-2. Also, the mixer circuit 3o is again connected to lthe selsyn transformer 10 through the contacts STR-3. When the system has reached this stage of operation, the motor operates in accordance with the signals provided by the voltage sources 20, 22, 24, 26 until the rotors are at the point where a minimum or no volt- -age is presented to the mixer` circuit 3G, at which point the object 42 will also be 'at its desired point or position. Thus, the invention, in effect, provides a source of signals which is utilized under predetermined conditions to operate the motor 4t) until the object 42 and the rotors o-f the selsyn transformers 10, 12, 14, 16 are within their range of unambiguous operation. Once this range is reached, the system operates in the manner of prior art positioning control systems.

Detailed Circuit Description The system in accordance with the invention which was described generally in connection with FIGURE l ywill be described in greater detail in connection with FIGURES 2(a) `and 2(1)). In FIGURES l, 2(a) and 2(b), the same 'reference numerals refer to the same elements. Also in the Various figures, the contacts associated with a particular relay winding bear the same legend as the u winding but are followed by a numerical suffix. FIG- URE 2(a) shows the selsyn ytransformers 10, 12, 14, 16, the mixer circuit 30, the discriminator 34, the motor control 33, the motor 40, the object 42, the relay discriminator circuit 54, and other operating portions of the system. FIGURE 2(1)) shows the voltage sources 20, Z2, 24, Z6 and the direction signal source 60.

With reference to FIGURE 2(a), the selsyn transformers 10, 12, 14, 16 each comprises three stators Iand `a rotor. The rotor of each of the transformers 1li, 12, 14, 16 is connected to the rotor of the next higher speed transformer through a gearing arrangement having a ratio of 1:10 as shown. The stator windings `or stators of the respective selsyntransformers 10, 12, 14, 16 lare connected in a Y-network. Two o-f the stators of each of the selsyn transformers 1o, 12, 14, 16 are coupled to -levels 1 and 2 of switch numbers 1, 2, 3, `and 4 respectively. The third stator of each of the selsyn transformers 1o, 12, 14, 16 is coupled to a ybus which is at some point of reference potential, such as ground. The respective rotors olf the selsyn transformers 10, 12, 14, 16 have one end coupled through interpolation transformers 2S to level 3 of switch numbers 2, 3, 4, and 5 respectively, and have the other end coupled to the mixer circuit 30. The two stators of the lowest or l-speed selsyn transformer 10 lare respectively coupled to levels 1 and 2 of switch number 1 through the normally engaged contacts STR-1. 'Ihe two stators of the lowest or l-speed selsyn transformer 10 may be respectively coupled to the test signal source of switch number l through the normally disengaged contacts STR-2. Likewise, one end of the rotor of the 1speed selsyn transformer 10 is coupled to the mixer circuit 30 through the normally engaged contacts STR-3. This rotor is also coupled to the relay discriminator S4 which comprises a suitable electron discharge device such as the triode vacuum tube shown. A resistor and capacitor are serially connected between the grid electrode of the selectron device and this rotor. The grid electrode is normally biased by some suitable source of unidirectional or direct current potential B- that is negative with respect to the reference potential so that some predetermined amount of voltage must be applied to the grid electrode before the electron device of the relay discriminator 54 can conduct. The anode of the electron device is coupled through the synchronizing relay winding SYR to a suitable source of potential provided by the secondary winding of a relay discriminator transformer 55. The electron device is conventionally connected in the manner shown. The primary of the relay discriminator transformer 55 is supplied lfrom a suitable source of alternating current potential when the contacts STR-4 are engaged in response to energization olf the synchronizing test relay winding STR. The particular input circuit of the mixer circuit 30` to which the voltage of the rotor of the l-speed selsyn transformer 10 is applied may be coupled to the point of reference potential through the normally disengaged contacts STR-5. The output circuit of the mixer circuit 30 is coupled to the discriminator 34, and the output circuit of the discriminator 34 is normally coupled to the motor control 38 through the normally closed contacts SYR-1. The discriminator 34 also includes an error monitoring relay winding EMR which remains energized as long as the mixer circuit 36 applies a signal to the discriminator 34, and which is deenergized in the absence of a signal from the mixer circuit 30. The motor control 33 may be supplied with -a signal from the direction signal source 6o when the contacts SYR-2 are engaged. The motor control 38 is coupled to the motor 4o through contacts LC-ll which are normally disengaged,

but which become engaged in response to energization of a loop contactor Winding LC. The motor 40 i's mechanically connected by suitable means, which may include gears or other mechanical devices, to the object 42 and to the rotor `otf the G-speed selsyn transformer 16 associated with the fourth and fifth digits. mentioned, the rotors of the respective selsyn transformers 10, 12, 14, 16 are mechanically coupled together through suitable gearing arrangements each having a predetermined speed step-down ratio of l0:l in a direction from the highest speed (MOO-speed) selsyn transformer 16 to the lowest speed (l-speed) selsyn transformer 10 so as to provide the speed ratios and relationships explained in the general description and operation.

The programed voltage sources 2i), 22, 24, 26 are shown in detail in FIGURES 2(a) and 2(1)). These voltage sources may comprise a plurality of stepping switches, the switch numbers corresponding to the respective digits of the instructed number. Each switch has one or more levels. Each level includes' an arm which rotates and engages one of a plurality of contacts which represent digits from zero to nine as indicated by the numbers on the inner side of the contacts. The switch contacts are connected to the taps of the secondary winding of a supply voltage transformer 27 in the manner indicated by the numbers adjacent the arrows. The voltages on the switch contacts are transferred to the engaging switch arms which are connected to the respective stators and rotors as indicated by the legends at the edges of FIGURES 2(11) and 2(b). The arms of the various levels of the stepping switches may be rotated to any predetermined position in accordance with programed dat-a which, yfor example, may be recorded on a magnetic tape or on punched cards in accordance with the instructed digits. In FIGURES 2(a) and 2(b), all of the arms of the various switches are shown in their home position. The arms rotate from their home position in a counterclockwise direction and engage the particular contact corresponding to the instructed digit. For example, if 4the yfirst digit of some instructed number were three, all of the arms of switch number l would rotate counterclockwise from 4the home position shown to the contacts having the number 3 by them, this being the fourth contact, since the first contact corresponds to an instructed number of zero. Thus, for an instructed number whose rst digit is three, the arm associated with level l of switch number l would engage the contact connected to the fifth transformer tap, the arm associated with level 2 of switch number l would engage the contact connected to the ninth transformer tap, the arm associated with level 3 of switch number 1 would engage the contact con- And, as already' mal or dropped out condition. f witha suitable source of energizing potential such as 115 volts, `6() cycles alternating current.

nected to a downscale direction signal, the arm associated with level 4 of switch number l, shown in FIGURE 2(a), would engage the contact connected to the eighth transformer tap, and the arm associated with level of switch number l, also shown in FIGURE 2(a), would engage the contact connected to the eleventh transformer tap.

The secondary winding of the supply voltage transformer 27 is `divided into two sections, one section having taps numbered 41 through l1, and 4the other section having taps numbered 12 through 22. Thus, each of the two sections provides ten incremental voltages which can be applied to the contacts of the various switches. In FIGURE 2(1)), it will be seen that 4the contacts of levels 1 and 2 of the switches are connected to the taps of the one section of the supply voltage transformer Z7, and that the contacts of level 3 of switch numbers 2, 3, 4, and 5 are connected to the taps of the other section of the supply voltage transformer 27. The test signal source 5t) shown in yFIGURE 2(a) also has its switch contacts connectedrto the one section of the supply voltage transing LC, and a positioning complete relay winding PCR are connected to one side of the supply voltage source. Each of the windings is connected to the other side of the supply voltage source through various combinations of normally engaged and/or disengaged contacts, the contacts being identifie-d V'by legends which associate them with their respective windings. A circuit including a diode and resistor connected in series with the time delay relay winding TDR and a capaci-tor connected in parallel with the time delay relay winding TDR is provided to delay energization and `deenergization of the time delay relay winding TDR, the delay depending upon the values of the resistor and capacitor. Two windings not shown in FIGURE 3, namely, the error monitoring relay winding EMR and the synchronizing relay winding SYR, are shown in FIGURE 2;(a). In all of the figures, the

respective contacts associated with a winding bear the former 27. Voltages applied to levels 1 and 2 of the y switches provide positioning to a resolu-tion of 36, and voltages applied to level 3 of the switches provide posi- .tioning to a resolution of 3.169. Levels 1 and 2 are coupled` to the stators of the selsyn transformers 10, I2, 14, I6 and level 3 is coupled to the rotors of the selsyn transformers 10, I2, 14, I6. Voltages applied to level 3 of the switches also provide positioning resolution to 11.36, these voltages being coupled to the rotors ofthe selsyn transformers Ill,

12, 14 through the interpolation transformers 28. These transformers have a voltage step-down ratio of ten to one in the direction of the lower switch numbers, or a voltage step-up ratio of one to ten in the direction of the higher'switch numbers. Thus, the voltage from level 3 ,of switch number 3 for the rotor of the 10-speed selsyn transformer .12 is stepped'down and also applied tothe rotorof the l-speed selsyn transformer lll throughthe' interpolation transformer 2S. The supply volta-ge trans- ;former 2.7 and the relay discriminator 'transformer 55 are supplied with a suitable energizing potentialrwhen the contacts SPR-1 engage as a result of a start positioning relay winding SPR becoming energized.v A vsuitable energizing potential is 115 volts, l60 cycles, alternating current. A `direction signal source 60 provides both positive and negative direct current voltagesV which may be connected to level 3 of switch number 1 in the manner indicated forcertain operations to be explained. These positive and negative voltages are used to operate the mov tor 40 in a forward or backward direction so as to move the object 4t2' toward the desired point or position. The K test signal sourceV 5l?, shown in FIGURE 2(a) as'levels 4 and 5 of switch number il, also derives its voltages from -taps on the secondary winding of the `supply voltage Ytransformer 27.

Relay Y Operation Ain FIGURES 2(a) and l2(b) and which are utilized in accordance with the invention. The relay windings tof FIGURE'3 are shown in their normal or droppedrout condition, [and hence the contacts are'also in 4their nor- A start positionng relay windingSPR Vis connectedacross this supply I. voltage through a start switch. This start switch is arranged so that it is only momentarily closed-either in response to a manual orV an automatic operation, and so that it subsequently opens. A time delay relay winding TDR, a locked-in timing relay Winding LTR, a syn,-V chronizing test relay winding'SrTR, a loop contacter wind- Y The relays are energizedV same legend as the winding but are followed by a number. FIGURE 4 shows waveforms illustrating the opof the respective waveform, and the deenergizedY condition of the relay winding is indicated by the lower portion of the respective waveform. Where a relay' becomes energized in response to energization of another relay at :some earlier time, the'operation of the later operating relay is indicated by an arrowhead on a dashed line. Thus, energization of the synchronizing test relayV winding STR causes energization of the synchronzingrelay winding SYR. Similarly, deenergization of the synchronizing test relay winding STR causes, after a predetermined time delay, deenergization of the time delay relay winding TDR. Y,

The following explanation of the relay operation and Sequence of operation can be more readily Vunderstood by reference to the waveforms shown'in FIGURE 4. Beginning at some arbitrary time zero, all of the relay windings are in the deenergiz'ed condition. VIt isV assumed that the voltage-sources Z0, 22, 24, 26, the direction signalsource 6l, and the test signal source Y50 shown in FIGURES k.7.(a) and 2(1)) have been set up to provide Y the predetermined voltages needed to cause Ythe object 4Z to moveto its desired position.Y These voltages` Vcan be set either manually or by means of some data reading n device such as a perforated tape. VClosing of the startV -switchaccomplishes the following `functions in the following approximate time sequence:

Y (l) The start positioning relay Winding SPR is 'enerregular instructing digits to the alternatev test-digits throug-htheV contacts STR-V1 and STRAZ.

(C) Disconnects the rotor ofthe lr-speed'selsyntrans- Y former 1d from the mixer'circuit 30 by meansof theV contacts ,STR-3,. and connects the reference potential bus to the mixer circuit 30 throughthe contacts STR-S.

(D) Starts the time delay pickup interval of Vthe V.time

delay relay winding. TDR through the contacts STR-6.

(3)V After a suitable time delay interval, assumed to be 50 milliseconds Vin LFIGURE 4, the time delay relayV winding TDR is energized and accomplishes Vthe-following-functions: f Y 'i (A) Energizes, f locked-inVV timing relaywinding LTRwhich locks itself in through thercontacts LTR-11. Y

throughs/.the Vcontacts YTDiR'fll, the

try

9 STR (by means of the contacts LTR-2) unless the synchronizing relay winding SYR has become energized in the meantime so that the contacts SYR-3 are engaged. The contacts STR-7 are engaged at this point. If the called-for position is outside the range of the programed voltage sources 20, 22, 24, 26, the synchronizing relay winding SYR in the relay discriminator circuit 54 becomes energized, and operation continues from this point.

(4) If the synchronizing relay winding SYR becomes energized, the following functions are performed:

(A) The `synchronizing test relay winding STR is locked in through the contacts SYR-S and STR-7.

(B) A direction signal from the source 60 is supplied from level 3 of switch number 1 to the motor control 38 through the contacts SYR-Z.

(C) The discriminator 34 is disconnected from the motor control 38 by means of the contacts SYR-ll.

(5) With the synchronizing relay winding SYR, the time delay relay Winding TDR, and the start positioning relay winding SPR all energized, the loop contactor winding LC becomes energized yth-rough the contacts SYR-4, TDR-2, and SPR-3. The loop contactor winding LC is locked in through the contacts LC-2 and thereby connects the motor control 38 to the motor 40 through the contacts LC-1.

(6) The motor 40 runs in the desired direction called for by the direction signal source 60 until it brings the object 42 within the range of control of the voltage sources 2t), 22, 24, 26. At this point, the magnitude of test signal present in the rotor or" the 1speed selsyn transformer has been reduced to a point where the synchronizing relay winding SYR becomes deenergized. Deenergization of the synchronizing relay winding SYR performs the following functions:

(A) Deenergizes the synchronizing test relay winding STR by means of the contacts SYR- (B) Switches the motor control 38 from the direction signal source 60 to the discriminator 34 through the contacts SYR-l and SYR-Z.

(C) Opens the initiating circuit for the loop cont-actor Winding LC by means of the contacts SYR-4.

(7) When the synchronizing test relay winding STR is deenergized, it initiates the following functions:

(A) Removes the supply voltage from the relay discniminator transformer 55 by means of the contacts STR-4.

(B) Switches the excitation of the stators of the l-speed selsyn transformer 10 from the test signal source 50 to the programed Voltage source through the contacts STR-1 and STR-2.

(C) Couples the rotor of the l-speed selsyn transformer 10 to the mixer circuit 30 through the contacts STR-3, and removes the reference potential bus from the mixer circuit 39 by means of the contacts STR-5.

(D) Initiates the deenergization timing interval, assumed to be 50 mill-iseconds in FIGURE 4, of the time delay relay winding TDR by means of the contacts STR-6.

(8) It" it is assumed that the object is still some distance (but within the range of operation of the voltage sources 20, 22, 24, 26) from its desired position, the rotors and interpolation transformers 28 of the selsyn transformers Iii, 12, 14, 16 apply voltages to the mixer circut 30, which in turn supplies a signal to the discriminator 34. As long as a signal is supplied to the discriminator 34, the error monitoring relay winding EMR is energized. With the error monitoring relay winding EMR energized, and with the synchronizing test relay winding STR deenergized, the following functions are accomplished:

(A) The loop contactor winding LC remains energized through the contacts STR-8, the contacts EMR-1, and the contacts SPR-3 even though the time delay relay winding TDR is deenergized.

(B) The motor 40 continues to drive the object 42 towards its desired position.

(9) When the object reaches its desired position, no further signals are applied to the discniminator 34 with the result that the error monitoring relay winding EMR becomes deenergized. Upon deenergization of the error monitoring relay winding EMR, the following is accomplished:

(A) The loop contactor winding LC is deenergized by means ofthe contacts EMR-1, and disconnects the motor control 38 from the motor 40 by means of the contacts LC-1.

(B) Deenergization of the loop contactor winding LC completes the circuit to the positioning complete relay winding PCR through the engaged con-tacts LC-3, SPR-4, LTR-3, and TDR-3. Energization of the positioning complete relay winding PCR may be used to return all relay windings to their normal condition, to provide an indication that positioning is complete, and may be used to initiate -another positioning operation.

If, at step number 3 above, the object 42 was within the range of the selsyn transformers 10, 12, 14, 16 (that is, the position `of the object 42 and the rotor of the selsyn Itransformer 10 are such that the Voltage supplied by the test signal source 50 is of insucient magnitude to cause energization of the synchronizing relay winding SYR but are such `as to cause energization of the error monitoring relay winding EMR), then during the period that the time delay relay winding TDR is energized, the loop contactor Winding LC will become energized through the contacts STR-8, EMR-1, and SPR-3, and positioning will be in the same condition as step 8 above. From this condition, the positioning will continue in a manner substantially similar through the remainder of the operations.

If, after one positioning cycle, a new instruction is applied to the system that duplicates the last previous instruction, then the system will first check for a large error while the time delay relay winding TDR is energized, and also for a small error of positioning while the time delay relay winding TDR is still energized. The loop contacter winding LC will not become energized because the synchronizing relay winding SYR and the error monitoring relay winding EMR do not become energized. Consequently, the positioning complete relay Winding PCR becomes energized as soon as the time delay relay Winding TDR is deenergized and indicates that the positioning cycle is complete and that the system is ready to receive additional instructions.

Positioning Operation The sys-tem in accordance with the invention permits unambiguous positioning of an object at any point Within a working zone equivalent to approximately 75% of a revolution of the lowest speed selsyn transformer. Thus, if the lowest speed selsyn transformer (which in FIGURE 2(a) would be ythe l-speed selsyn transformer 10) of a positioning system has a range of inches for one complete rotation or revolution, then a positioning system in accordance with the invention permits unambiguous posiitioning in one step between any two points in a free working zone of 75.0 inches. Positioning outside this working zone is also possible with one or more smaller steps each having a range substantially equivalent to 10% of a revolution of fthe lowest speed selsyn transformer. FIGURE 5 shows a table of test numbers and direction signals for each of the first digits of instructed numbers vfor a positioning control system in accordance with the invention that has a working zone of 0.0 to 75.0 inches. As an example of operati-on, it has been assumed that the position called for is 60.000 inches. Under fthe digit 6 of FIGURE 5 it is seen that the test number for such a position is 8 and the direction of travel is up (indicated by the letter U, as opposed to the letter D for a down direction). FIGURE 6 shows voltage waveforms representative of the test number signal and the selsyn transformer signal across the rotors, after being combined in the mixer circuit 30, as plotted against the position or location of the object 42 for the particular example assumed. Thus, the selsyn transformer signal across the rotors has a minimum or zero value at the position of the instructed number, namely 60.000 inches, and the test number signal across the rotor of the l-speed selsyn transformer 110 has a minimum or zero value at the position or location called for by the table shown in FIGURE 5, namely 80.000 inches. If the object is at a location outside the range of one step of unambiguous operation of the selsyn signal, the test number signal across the rotor has suicient magnitude to cause energization of the synchronizing relay winding SYR which causes the motor 40 to move the object 42 upscale as indicated by the arrow adjacent the test number signal. As the object 42 is moved in the upscale direction, the test number signal amplitude across the rotor decreases until it falls below a predetermined level (indicated in FIGURE 6 as the synchronizing relay pickup threshold). At this point, the synchronizing relay winding SYR is deenergized and the error monitoring relay winding EMR in the discriminator 34 takes over and completes the positioning to the previously instructed number of 60.000 inches. 1f, in the example assumed, the previous positioning left the object 4Z within the range of one step of fthe selsyn signal positioning (that is, between 20.000 inches and 75.000 inches), then the selsyn transformers 10, 12, 14, 16 can provide the proper positioning without the use of the f test number signal and the synchronizing relay winding SYR. As a practical matter, the relay discriminator 54 will cause operation or energize-tion of the synchronizing relay winding SYR at any point between 0.0 inch and approximately 36.00 inches because the test number signal has an amplitude across the rotor suiciently large to overcome the bias on the grid electrode of the electron Vdevice of the `discriminator 54 and cause the synchronizing relay winding SYR to be energized. While the selsyn transformers 10, 12, 14, 16 are capable of bringing about the proper positioning between 20.000 inches and 75.000 inches for the particular example assumed, the selsyn transformers 10, 12, 14, 16 clearly cannot bring about proper positioning in a single step if the object 42. was previously left somewhere in the range between 0.0 inch and 20.000 inches. This is lbecause the selsyn transformer signal oscillates or fluctuates considerably as shown in FIGURE 6, with the result that ambiguous positioning might be brought about. lf the object 42 is -at some point in the range between 0.0 inch and V361.000 inches the syncirronizing relay winding SYR is energized and causes movement of the object 42 in the upscale direction as indicated. However, once the test number signal amplitude across the rotor falls below a predetermined level (indicated in FIGURE 6 as the synchronizing relay pickup threshold), the synchronizing relay winding SYR is Y deenergized and the error monitoring relaywinding EMR in the discriminate; 34 takes over and completes the positioning to the instructed number of 60.000 inches. While FIGURE 6 shows only one example of the waveiormsfor a particular instructed number, persons skilled in the art will realize that for a different instructed number the waveforms occupy different positions. For example, if

the instructed number is 00.100 inch, the selsyn signal has a minimum tor zero value at that point. And, examination of FIGURE 5 shows that for Van instructed number of 00.100 inch, the test number is 3 and travel is in the downscale direction. Thus, the test number signal (which in FIGURE 6 is shown -as having a minimum or zero value at 80.000 inches) would be moved to the `left so that it has a minimum or'zero value at 30.100 inches. The selsyn signal would have a minimum or zero value at the instructed number, namely 00.100 inch. Positioning from various points in the working zone would be brought about either by the selsyn transformers 10, 12, Y14, 16 alone, or by the test signal and thel discriminator 54 operating with the selsyn transformers 10, 12, 14, 16.

FIGURE 5 also shows alternate .test numbers for instructed numbers having first digits beginning with 8 and 9, these first digits being outside of the free working zone between 00.00 and 75.00 inches. It is not always possible to position an object from a point within to a point outside of the free working zone in one step. In fact, positioning outside the free working zone may be limited to -a range of 10% of a revolution of the lowest speed rotor. Hence, it may be necessary to position the object near the appropriate edge of the free working zone and then provide the selsyn transformers with one or more appropriate instructions for positioning outside of the free working zone. Since positioning outside the free working zone may be limited to a range of 10%, the number of instruction numbers depends upon the distance between the desired point and the appropriate edge of the free working zone. As an example, assume that the last positioning opera-tion lett the object at 40.00 inches in the free working zone, and that it is desired to position the object at 80.00 inches, a location just outside of the free working zone. The rst step in bringing Y this positioning labout is to move the object to a point just within the free Working zone at the edge nearest the desired position, namely 80.00 inches. This is done by providing an instructed number of 75.00 inches and allowing the lobject to be positioned at this loca-tion in the manner described previously. Then, the systemis given the instruction number for the desired position out- Y side of the free working zone, namely 80.00 inches. An examination of FTGURE 5 will show that for this nurnber, the alternate test number is 00.00 inch and travel is in the downscale direction. However in this situation, the selsyn signal will have a minimum at 80.00 inches, and will bring the desired positioning about because the object will not be in the area of the test number signal in which the synchronizing relay SYR is energized. Consequently, positioning will be brought about only by the selsyn signal. The alternate test number signal would halve no function in this particular positioning situation. However, the test numbers are given in FIGURE 5 to show the functions which the arrangement in accordance with the invention will perform under these circumstances.

Up to this point, the operation and positioning of the system in accordance with the invention has been described primarily in terms of a linear or straight-line travel. However, it is important to no-te that the system in accordance with the invention can be used equally Ywell Vin a rotational positioning system. Furthermore,

thisrotational positioning system can be used in a prescribed free working zone just as the straight-line posi- Y tioning system previously described and also'in continuous rotational positioning in which the free working zone travels o-r moves along with lthe rotational positioning so that the restriction of small steps (described in connection with the straight-line positioning system) is not'present. In arrangements in which continuous rotational positioning is possible and desirable, there are four possible modesV of operation. These four modes are: Y

1) Travel in a downscale direction by the discriminator signal.

(2) Travel in the upscale direction by the discriminator signal.

(3) Upscale direction of travel favored.

(4) Downscale direction of travel favored.

ln these four` modes of operation, it is necessary to dij vide onerrevolution of the lowest speed selsyn transformer motion into 1,000; 10,000; 100,000 pants, or some multiple thereof. `In these four modes, control of the system will go directly fromone instructed number Vto any Aother instructed number although the control will frequentlyV Vgo around in a longer direction (that is, in the direction inVV which it would travel more than 1805V of a revolution) Yof the rlowest speed selsyn transformer. VExamples of the'Y four modes of continuousrotational travel are shown by the waveforms in FIGUREVZzand are described below;

Several relatively minor modiiications would have to be made in the diagram shown in FIGURE 2(a) to accommodate the first two modes of operation, namely downscale and upscale travel by the discriminator 34. First, the normally open contacts SYR-2 of the synchronizing relay SYR would be disconnected from level 3 (the direction signal source 60) of switch number 1. Second, additional contacts SYR-5 and SYR-6 would be added to the synchronizing relay SYR. Third, contacts SYR-S would be normally open and would be placed in parallel with contacts STR-3 of the synchronizing test relay STR. Fourth, contacts SYR-6 would be normally closed and would be placed in series with contacts STR-5. Fifth, a direct connection would be made across contacts SYR-1. And finally sixth, the test signal source 50 would be modified to provide a test number (sometimes referred to herein as an alternate test number) which has a value determined by which of the two modes of operation is'to be used. These modifications remove the direction signal source 60` (as previously described) from the system and permit the test signals to be applied to the mixer circuit 30, the discriminator 34, and the motor control 38 during the time that the synchronizing relay SYR is energized. It will be recalled that the synchronizing relay SYR is energized if .the test signals have a magnitude which exceeds some predetermined value. The actual path for applying these ltest signals to the mixer circuit 30 would include the closed contacts STR-2, the stator and rotor of the l-speed selsyn transformer 10, and the closed contacts SYR-5 in parallel with the open contacts STR-3i. v The reference potential bus connection provided by the closed contacts STR-5 would be removed by the open contacts SYR-6.

In this way positioning may be provided by test numbers which operate through the mixer circuit 30 and the discriminator 34. As the desired position is approached, the synchronizing relay SYR will eventually become deenergized (as in the previous description) and final positioning would ybe provided lby the regular selsyn transformer signals operating through the mixer circuit 30 and the discriminator 34.

In the first mode of operation, namely travel in a downscale direction by the discriminator signal, directional signals are not required from level 3 of the stepping switches since the discriminator signal is at all times provided with the proper downscale polarity. The test signal source `50 is modified to provide an alternate test number which is always three greater than the first digit of the instructed number. The phase of the relay descriminator 54 anode voltage is given in the legend of FIGURE 7. In FIGURE 7, P.U. means picked up or 'energized and D O. means dropped ont or deenergized.

In operation, the system prefers to travel in the downscale direction (indicated by arrows pointing to the left), unless the desired position in the upscale direction is less than one-eighth to one-third part of a revolution of the lowest speed selsyn transformer. Thus, the maximum possible upscale travel, (indicated by arrows pointing to the right) varies from approximately oneeithth part of a revolution for numbers whose last digits (that is, after the first digit) are all zeros to approximately one-third of a revolution for numbers whose last digits are all nine.

In the operation described as travel in the upscale direction by the discriminator signal, directional signals are likewise not required from level 3 of the stepping switch A since the discriminator signal is always provided with the proper polarity. In this operation, the test signal source 50 is modified to provide an alternate test number which is alwaysthree less than the rst digit of the instructed number. The phase of the anode voltage of the relay discriminator 54 is lreversed as indicated in the legend of FIGURE 7. The system prefers to go in the upscale direction unless the position desired in the downscale direction is less than one-eighth to one-third of a revolution of the lowest speed selsyn transformer. Thus, the maximum downscale travel varies from approximately one-third of a revolution of the lowest speed selsyn transformer for numbers whose last digits are zeros to approximately one-eighth of a revolution of the lowest speed selsyn transformer for those numbers whose last digits are all nine.

Several relatively minor modiiications would have to be made in the diagram of FIGURE 2(a\) to accomplish the Second two modes of operation, namely downscale and upscale travel favored. First, the normally open contacts SYR-2 of the synchronizing relay SYR Iare connected to either Ian upscale or a downscale signal. Second, the test signal source Si) would be modified to provide a test number which has a value determined by which of the two modes of operation is to be used. When the synchronizing relay SYR is operated, the motor control 38 either always receives an upscale signal for upscale travel favored or `always receives a. downscale signal for downscale travel favored to provide positioning. When the synchronizing relay SYR is not operating, positioning is provided by the selsyn transformer signals operating through the mixer circuit 3i) and the discriminator 34.

In the mode of operation termed upscale direction of travel favo-red, the test signal source 50 is modilied to provide an alternate test number which is always three greater than the first digit of the instructed number. The phase of the anode voltage of the relay discriminator 54 is given in the legend of FIGURE 7. The normally open contacts SYR-2 of the synchronizing relay SYR -are permanently connected to a signal source that runs or operates the system in the upscale direction whenever the synchronizing relay isl energized. This arrangement has the advantage over the operation of upscale travel -by the disoriminator signal in that the longest rotational operation in the upscale direction is limited to a maximum of approximately 240. In this operation, the maximum possible downscale operation is limited to approximately 120.

In the mode of operation termed downscale direction of travel favored, the test signal source S0 is rnodied to provid-e an alternate test number which is always three less than the first digit of the instructed number. In this operation, the phase of the anode voltage of the relay discrirninator circuit 54 is reversed as indicated in the legend of FIGURE 7. The normally open contacts SYR-2 of the synchronizing relay SYR are permanently connected to a signal source that runs or operates the system vin the downscale direction whenever the synchronizing relay SYR is energized. This arrangement has the advantage over the operation of downscale travel by the discriminator signal in that the longest rotational operation in the `downscale direction is limited to a maximum of approximately 240. The maximum possible upscale operation is limited to approximately 120.

The arrangements in accordance with the invention can, as will be appreciated by persons skilled in the art, provide many modes of operation and provide a flexible system which can be adapted to the needs of a particular operation. The invention provides improved positioning control which extends the free working zone of positioning beyond those limits imposed by systems utilizing only selsyn transformers. Furthermore, this free Working zone is extended Without requiring additional selsyn transformers and is brought labout A'by the addition of relatively simple and inexpensive circuit components. While the invention has been described with reference to particular embodiments, it is to be understood that modications may be made by persons skilled in the art without departing from the spirit of the invention or from the scope of the claims.

What I claim as new and desire to secure by Letters Patent of the United States is:

l. An arrangement for bringing `an object within the a drive device and that is capable of positioning said object at a point within said range in accordance with a signal from ya selsyn device, comprising a source that pr duces a direction sign-al having a selectable value, and means for alternatively coupling said drive device to said selsyn deviceand for coupling said drive device to said direction signal source for determining the operation of said drive device.V

2. An arrangement for bringing Aan object within the range of operation of a follow-up control system that has a drive device and that is capable of positioning said object from one point Within said range to lanother point Within said range in accordance with a signal from a selsyn device, comprising Va source that produces a direction signal having -a plurality of selectable values, a test signal source, means for selectively coupling said test signal source to said selsyn device, and means for alternatively coupling said drive device to said direction signal source in response to certain values vof said test signal derived from said selsyn device for causing said drive device to bring said object within said rangeV and for coupling said drive device to said selsyn device in response to certain other values of said test signal derived from said'sel-syn deviceY for causing said drive device to position said object within said range.

' 3. An arrangement for bringing an `object Within the range of operation of a follow-up control Isystem having a selsyn device that is capable of controlling a drive device Within said range of operation in `accordance with `a signal from a rst source, comprising a source that produces a direction signal having Va plurality of selectable values, first means adapted to be coupled `to said selsyn device for deriving a rst signal therefrom which varies as a function f of the location of said object, means coupled to said iirst means for comparing said l`1rst signal with a 'reference signal and producing a -second'signal which varies as 'a function of said rst and said reference signals, and meansV y for Ialternatively coupling said drive device to saiddirection signal source in response to certain vcharacteristics of said second signal for causing said drive device to bring said object within said range and for coupling said drive device to Vsaid Vselsyn device in response to certain other characteristics of said second signal for causing said drive device to position said object Within said range.

4. An arrangement` for `,bringing an object Within the range of operation Iof a follow-up control system having a Vselsyn device that controls a drive device for moving said object from a iirst point Within said range to Ia second Y point Within said range in accordance With la signal applied to said selsyn device, comprising a source that produces a test signal having a plurality of selectable values, means! for selectively coupling said test signal source to said selsyn device, means for comparing a test signal derived from said selsyn device with` a reference signal and producing la rst signal which varies as a function of the relation of said derived test signal and Vsaid `reference signal, a

Y direction signal source, andV means for alternatively coup-V ling said drive devicet-o said'direction Vsignal source in response to certain values of said first signal for operating Vsaid drive device to bring said object Within said rangeY and for coupling said device to said selsyn device Yin rep sponse to certain other values Iof `said first signal for operating saidfdrive device to'p-osition, said object `Within said range. i l Y 5. Anarrangement'for bringing an object Within the range of operation ofV a followaup control system havingV `a drive device and a selsyn device capable of moving said Y objectV from some point within said range to a desired point Within said range in accord-ance with a predetermined Y Y signal applied'to said selsyn device, comprising a source that produces a test signal having a plurality `of selectable values'dependent upon thesdesired location of said object,

means for Aselectively coupling Vsaid test signalY source toV s-aid'selsyn device, a discrirninatoiW circuit adapted'to be YVco'iupled to said selsyn device for comparing a test signal 'Y derived therefrom with the value of la reference Vsignal and f l l producing a discriminator signal which varies as a Yfunction of the relative values of said derived test signal and sai reference signal, a source that produces a direction signal for determining the direction of Voperation of said drive device to ybring said object Within said range, and means responsive to said discriminator circuit for alternatively coupling `said drive device to said direction signal source in responserto certain values of said discrimnator signal so as to bring said object Within said range and for coupling said drive device to said selsyn device in response to certain other values of said discriminator sign-al so las to move said object to said desired location within said range.

Y6. An arrangement for bringing an object Within the range lof operation of `a follow-up control system comprising a drive device and a plurality of selsyn devices capable of moving said object from some point Within said range to a desired point within Isaid range in accordance with predetermined'signals applied to said selsyn devices, a source that produces a test signal having a plurality of selectable values dependent upon the desired location lof said object, means` for selectively coupling said test signal source to one of said selsyn devices, means for selectively decoupling said.V predetermined signals from `said one selsyn device, a discriminator circuit coupled to said one selsyn device for comparing a test signal derived therefrom with the value Vot a reference signal and produc- 5 ing a discriminator signal which variers as a function ofV the relative values of said derived test signal yand said reference signal, a sour-ce that produces a `direction signal for determining the direction of operation of said drive device to Vbring said object Within said range, and means coupled to said drive device `and responsive to said dis'- criminator circuit for alternatively,coupling said drive device to said direction signal source in response to certain values of said discriminatori" signal Vso as to bring said object Within -said range and for coupling said drive device to said selsyn devices in response to certain other values of said discriminatori signal so as to move said object to said desired location Within said range.

7. An :arrangementlfor bringing `an obect Within the Y range `of operation of a follow-up cont-rol system` that is capable of positioning said object'from a first point Within Ysaid range to a desired point WithinV said range,rsaid sys-V tem havinga drive device that is operated in Vaccordance With 'a predetermined signal `applied toY a selsyn device,

comprising a source that producesY a test signal having. a-value dependent upon the desired location of said object,

said range, a sourcethatproduces la direction signalV for operating said drive devicel so as to bring said object within said range, and means responsive Vto said discriminator l circuit for 'alternatively coupling said drive device Vto said direction signal source 'in' response to certain values of saiddiscrimina-tor signal so as tobring said object within Y y said range and for coupling said drive devicesto said selsyn device in response to certain other'values of saiddiscriminator signal so as to move said object to said desired loca- Ytion within said ranger g 8.'An arrangement-for bringing an object within'the range of operation of a Vfollowup control system that is capable of positioning said objectV between points inside i said range, said system having a drive device thatis operated in accordance with Va 'predetermined signal Vapplied to'a selsyn device, comprising asource that produces a j test signal that has a value dependent upon the :desired location of said object withinfsaid range, a discriminato'rY circuit for comparing a derivedrvalue of said'test signal with the value of a reference signal Vand'producing a dis.

criminator signal which varies as a function of the relative values of said derived test signal and said reference signal, means selectively coupling said test signal source to said discriminator circuit and adapted for simultaneously decoupling said selsyn device from said drive device during the time said object is outside said range and selectively decoupling said test signal source from said discriminator circuit and adapted for simultaneously coupling said selsyn device to said drive device during the time said object is within said range, a source that produces a direction signal for operating said drive device so as to bring said object within said range, and means responsive to said discriminator signal for alternatively coupling said drive device to said direction signal source in response to certain values of said discriminator signal so as to bring said object within said range and for coupling said drive device to said selsyn device in response to certain other values of said discriminator signal so as to move said object to said desired location within said range.

9. An arrangement for bringing an object within the range of operation of a follow-up control system that is capable of positioning said object between points inside -said range, said system having a drive device that is operated in accordance with a predetermined signal derived from a selsyn device, comprising a source that produces a test signal that has a value dependent upon the desired location of said object within said range, said test signal being selectively applied to said selsyn device, a discriminator circuit coupled to said selsyn device for comparing the value of said test signal derived from said selsyn device with the value of a reference signal and producing a discriminator signal which varies as a function of the relative values of said derived test signal and said reference signal, means for selectively coupling said test signal source to said selsyn device and adapted for simultaneously decoupling said selsyn device from said drive device during the time said object is outside said range and for selectively `decoupling said test signal source from said selsyn device and adapted for simultaneously coupling said selsyn device to said drive device during the time said object is within said range, a source that produces a direction signal for operating said drive device so as to bring said object within said range, and means responsive to said discriminator signal for alternatively coupling said drive device to said direction signal source in response to certain values of said discriminator signal and thereby bring said object within said range and for coupling said drive device to said selsyn device in response to certain other values of said discriminator signal so as to move said object to said desired location within said range.

10. An arrangement for bringing an object within the range of operation of a follow-up control system that is capable of positioning said object between selected points inside said range, said system having a drive device that is operated in accordance with a predetermined signal derived from a selsyn device, comprising a source that produces a test signal that has a value dependent upon the desired location of said object within said range, a discriminator circuit adapted to be coupled to said selsyn device for comparing the derived value of said test signal with the value of a reference signal and producing a discriminator signal which varies as a function of the relative values of said derived test signal and said reference signal, a synchronizing test relay having a winding that is energized in response to a synchronizing relay winding being energized and that is deenergized in response to said synchronizing relay winding being deenergized, said synchronizing relay winding being coupled to said discriminator circuit and being energized in response to certain values of said discriminator signal and being deenergized in response to certain other values of said discriminator signal, first contacts adapted to be coupled between said selsyn device and said drive device, said first contacts being engaged in response to said synchronizing test relay winding being deenergized and being disengaged in response to said synchronizing test relay winding being energized, second contacts adapted to be coupled between said test signal source and said selsyn device, said second contacts being disengaged in response to said synchronizing test relay winding being deenergized and being engaged in response to said synchronizing test relay Winding being energized, la source that produces a direction signal for operating said drive device so as to bring said object within said range, third contacts adapted to be coupled between said direction signal source and said drive device, said third contacts being disengaged in response to said synchronizing relay Winding being deenergized and being engaged in response to said synchronizing relay winding being energized, and fourth contacts adapted to be coupled between said first contacts and said drive device, said fourth contacts being engaged in response to said synchronizing relay winding being deenergized and being disengaged in response -to said synchronizing relay winding being energized.

1l. An :arrangement for bringing an object within the range of operation of `a follow-up control system that has a drive device and tha-t has selsyn devices supplied from ya voltage source and that is cap-able of positioning said object from one point within said range to another point Within said range in accordance with signals lfrom said selsyn devices, comprising .a test signal source, and means yfor alternatively coupling said drive device through one of said selsyn devices to said test signal source in response to certain derived values of said Ktest signal for causing said drive device to bring said object within said range and for coupling said drive device through said one selsyn device to said Voltage source in response to certain other derived values of said test signal for causing said drive device to position said object within said range.

l2. An arrangement for bringing an object within the range of operation of Ia follow-up control system having a selsyn device that controls a drive device for moving said object from a first point within said range to a second point within said range in accordance with a signal from `a iirst source applied to said selsyn device, comprising a source that produces a test signal having a plurality of selectable values, means for comparing `a derived test signal with a reference signal and producing a second signal which varies as a function of the relation of said test and said Ireference signals, and means for alternatively coupling said drive device through said selsyn device to said test signal source in response to certain values of said second signal for operating said drive device to bring said object within said range and for coupling said drive device through said selsyn device to said lirst signal source in response to certain other values of said rst signal for operating said drive device to position said object within said range.

13. An arrangement for bringing `an object within the range of operation of a follow-up control system that is capable of positioning said object from a iirst point within said range to a desired point within said range, said system having a drive device that is operated in accordance with a predetermined signal from a rst source which is applied to a selsyn device, comprising ya source that produces a test signal having a value dependent upon the desired location of said object, a discriminator circuit for comparing a derived value of said test signal with che value of a reference signal and producing a discriminator `signal which varies as a function of the relative values of said derived test signal and said reference signal, means for selectively coupling said test signal source through said selsyn device to said discriminator circuit during the time said object is outside said range, and means responsive to said discriminator circuit for ialternatively coupling said drive device through said selsyn device to said test signal source in response to certain values of said discriminator signal so as to bring said object within said range and for coupling said drive device through said 19 20 selsyn device to said first signal source in response to 2,796,569 McDonald June 18, 1957 Certain other values of said discriminator signal so as to 2,848,670 Kelling et al Aug. 19, 1958 move said object to said desired location Within said range. 2,905,877 Ciscel Sept. 22, 1959 References Cited in the iile of his patent UNITED STATES PATENTS Gille Dec. 1, 1953 OTHER REFERENCES Savant, C. J.: Basic Feedback Control System Design,

2,661,449 pages 23S-,239, McGraw-Hill, New YoTk, 1958.

UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 3o35v214 May 15 1962 Leroy Ua C. Kellng It is hereby certified that error appears in the above numbered patent requiring correction and that the seid Letters Patent should read es corrected below.

Column 2, line 47u for' "operations" read operation, column 5 line 68, for "Solectron" read electron column 13, line 'Z5 after "one-third" insert part Column 15, line. 60Y after "said"Q first occurrence; insert drive column 16MI line 2T for "variare" read varies Signed and sealed this 28th day of August 1962.

(SEAL) Attest:

ESTON G. JOHNSON DAVID L; LADD Attestiug Officer Commissioner of Patents 

